Autoinduction, asymmetric amplification

Asymmetric amplification, 551,700-712 in carbonyl-ene reaction, 551 in diethylzinc addition, 702 Asymmetric autoinduction, 713 Asymmetric aziridination, 317-322 mechanism of, 320 with copper catalysts, 317-321... 

The most fully understood system in this class of reactions, however, is the DAIB-catalyzed addition of diethylzinc to aldehydes, due to the very detailed mechanistic studies performed by Noyori et al.32-37 They were able to determine the structure of several intermediates involved in the reaction and established the kinetic law. Part of the catalytic cycle is depicted in Scheme 13. The origin of the asymmetric amplification lies in the formation of dimers of DAIB-zinc alkoxides. The heterochiral dimer is quite stable in the concentration range of the experiment (2 x 10 1 to 5 x 10 1 M in toluene for DAIB), whereas the homodimers are prone to dissociation and react further with diethylzinc to give a di-zinc complex that is the active species in the catalytic cycle. They react with benzaldehyde and give rise to the asymmetric transfer of the ethyl group. The final product, as a zinc alkoxide, does not interfere with the reaction (and hence there is no autoinduction), since it... 

The cpl-induced asymmetry in photoreactions as described in Sec. B. of this chapter is not very pronounced. In order to obtain ees in excess of a few percent, photodestruction must be chosen and most of the reactant material must be sacrificed. Therefore amplification mechanisms for all types of cpl-induced asymmetric photoreactions would be highly desirable. Autocatalysis, i.e., an asymmetric synthesis where a chiral product acts as a catalyst for its own production [128], and autoinduction, i.e., the stimulation of a chiral catalyst by a chiral product [44,129], are options. Autocatalytic systems that will tilt to one enantiomeric side were introduced by Frank [130] and Seelig [131]. 

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